Power factor corrected UPS with improved connection of battery to neutral

ABSTRACT

An uninterrupted power supply (UPS) device with uninterrupted neutral from input to output utilizes the same converter for converting rectified AC power and battery power to positive and negative high voltage (HV) rails. A simple circuit is utilized for connecting the battery to the conversion components of the PFC circuit without adverse affect on the performance of the PFC circuit, and while holding the battery substantially connected to neutral. In a first embodiment, the circuit comprises a simple combination of four diodes and a pair of high pass capacitors arranged so that in both power line and battery supply modes the battery is balanced around neutral. In a second, preferred embodiment, one terminal of the battery is connected directly to neutral.

BACKGROUND OF THE INVENTION

[0001] 1. Field of the Invention

[0002] This invention relates to uninterrupted power supply (UPS)apparatus and, more particularly, to a power factor corrected UPSmaintaining integrity of the connection from power line neutral to anoutput load terminal.

[0003] 2. Description of the Prior Art

[0004] UPS systems are now widely used to provide a secure supply ofpower to critical loads such as computers, so that if the line voltagevaries or is interrupted, power to the load is maintained at an adequatelevel and is not lost. The UPS conventionally comprises a rectifiercircuit for providing a DC voltage from the AC power lines; an inverterfor inverting the DC voltage back to an AC voltage corresponding to theinput, for delivery to the load; and a battery and a connection circuitfor connecting battery power to the input of the DC to AC inverter, sothat when reliable AC power is lost the delivery of AC power to the loadis substantially unaffected. In such an UPS, it is highly desirable tomaintain an uninterrupted neutral from the commercial AC utility powerto each component circuit and to the load, e.g., in order to eliminateshock hazards. Because of the inherent nature and mode of operation oftypical UPS systems, conventional UPS designs did not maintain theintegrity of the neutral through the processing circuitry, requiringsome type of isolation means such as isolation transformer tore-establish the neutral at the load. U.S. Pat. No. 4,935,861, assignedto the assignee of this invention, provides an UPS wherein theelectrical continuity of an electrical conductor is maintained from oneterminal of the AC utility through to one of the load terminals, withoutany isolation means being required.

[0005] The problem with maintaining integrity of the neutral is furthercomplicated in a UPS having a power factor correction circuit. The taskof connecting the battery to neutral is simple in a power supply unitwithout a PFC circuit, such as shown in U.S. Pat. No. 4,823,247. But asis well known, there are important reasons for incorporating powerfactor correction (PFC) into an UPS. And, the incorporation of such aPFC circuit imposes additional difficulties upon the goal of maintainingintegrity of a neutral connection from the power line to the load. Adesign for achieving an uninterrupted power supply system having a PFCcircuit is disclosed in U.S. Pat. No. 4,980,812, also assigned to theassignee of this invention.

[0006] It is recognized that maintaining the integrity of the neutral inan UPS offers advantages of lower cost, due to lack of need forisolation means, and higher reliability. Because of the design criterionof an undisturbed neutral, an UPS with a PFC circuit has heretoforerequired three converters. As seen in FIG. 1, such a prior art apparatuscontains a converter as part of the power factor correction circuit, theoutput of which provides DC on a positive high voltage (HV) rail andindependent negative HV rail respectively relative to the neutral line.The DC-AC inverter is necessarily a second converter, and, a thirdconverter circuit has been necessary to connect the DC from the batteryto the HV rails. Prior art attempts to combine the battery converterwith the PFC converter have always resulted in either an isolated UPS,wherein the neutral is not maintained, or some circuit arrangement forconnecting the DC output of the battery into an AC voltage which couldbe utilized by the AC to DC converter portion of the PFC circuit. Forsafety reasons, it is desirable to effectively connect the battery tothe neutral, which leaves an unfulfilled need for an efficient andreliable manner of translating the battery output to the HV rails. Thedesign solution of having a third converter of some different kind, orthe option of using an isolation transformer, both have obviousdisadvantages. The problem is thus how to provide that the convertedoutput from the PFC circuit, as well as the battery output, can beindependently loaded and still balanced around neutral to the plus andminus HV rails without using a separate converter of some sort for each.Stated differently, the problem for which a solution has not heretoforebeen known is how to connect the battery to the HV rails utilizing thePFC converter, while effectively maintaining a connection from thebattery to neutral.

SUMMARY OF THE INVENTION

[0007] It is an object of this invention to provide a power factorcorrected UPS which maintains neutral integrity from the input of theUPS to an output terminal to which the load is connected, the UPS devicehaving a simple and efficient circuit for connecting the battery to theconverter of the PFC circuit, whereby whenever the battery providesoutput power due to deterioration of the utility line voltage, batteryvoltage is converted through the PFC converter and delivered to the highvoltage rails. The UPS achieving this object provides an uninterruptedneutral from its input connection to the AC power line through to anoutput terminal for connection to the load, balances the battery aroundneutral, and achieves supply of the battery power independently to thehigh voltage rails without the need of an independent battery to HV railconverter, or the need for any isolation means.

[0008] In a first embodiment, a four diode-two capacitor circuit is usedto connect the battery to the PFC converter. During normal operationwhen the UPS is drawing power from the utility line, the battery isbalanced around neutral and is maintained no more than one forward diodedrop away from neutral. By using a battery with a voltage less thanone-half of the peak of the incoming AC voltage, the PFC circuit issubstantially unaffected so that power factors greater than 0.9 can beachieved. During loss of AC input, when the UPS runs on battery,switching elements of the PFC converter are independently turned on andoff, enabling conversion of the battery voltage through the PFCconverter circuitry to the HV lines. In a second, preferred embodiment,one terminal of the battery is connected directly to neutral, and theother terminal is connected through a normally open switch and a diodeto the converting circuit. The switch is closed when low AC power linevoltage is sensed. Both embodiments thus enable elimination of aseparate converter for the battery while preserving the advantages ofprior art power factor corrected UPS devices maintaining integrity ofthe neutral connection from input to load.

BRIEF DESCRIPTION OF THE DRAWINGS

[0009]FIG. 1 is a simplified block diagram showing the primarycomponents of a prior art power factor corrected UPS.

[0010]FIG. 2 is a simplified circuit diagram of a power factor correctedUPS with neutral integrity, and illustrating the problem of connectingthe battery to the HV rails without the aid of a converter dedicated tothe battery.

[0011]FIG. 3 is a circuit diagram showing a first embodiment of theimproved connection circuit of this invention, whereby the battery isconnected to the converter of the PFC circuit while maintaining thebattery balanced around neutral.

[0012]FIGS. 4A and 4B are circuit diagrams illustrating a cycle ofoperation when the UPS of FIG. 3. is drawing power from the AC input,and the line or energized AC input terminal is positive relative to theneutral terminal.

[0013]FIGS. 5A and 5B are circuit diagrams illustrating a cycle ofoperation when the UPS of FIG. 3 is drawing power from the AC input, andthe line or energized AC input terminal is negative relative to theneutral terminal.

[0014]FIGS. 6A and 6B illustrate operation of the improved UPS circuitof FIG. 3 during a condition of unacceptable AC input and UPS batteryoperation.

[0015]FIG. 7A is a circuit diagram of a preferred embodiment of theinvention, wherein one terminal of the battery is connected directly toneutral.

[0016]FIGS. 7B and 7C are circuit diagrams illustrating a cycle ofbattery-driven operation for the circuit of FIG. 7A.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0017] Referring now to FIG. 2, there is shown a circuit diagram of atypical power factor corrected UPS with an uninterrupted neutral frominput to output. The AC input is connected to the UPS at two inputterminals, one of which is marked “line” and the other of which ismarked “neutral.” The neutral line is connected by an uninterruptedconductor to one of two output terminals, across which AC output poweris delivered. The AC input signal is connected across a first capacitorC1. The line terminal is connected to rectifier diodes D1 and D2. D1 isin series with inductor L1, the other side of L1 being connected throughswitching transistor Q1 to neutral. D2 is connected in series withinductor L2, the other side of L2 being connected through switchingtransistor Q2 to neutral. The input terminals 31, 32 are driven byswitch control means 33 such as illustrated in FIG. 1 of U.S. Pat. No.4,980,812, incorporated herein by reference. Transistors Q1 and Q2 ofFIG. 2 correspond to transistors 86 and 88 seen in FIG. 1 of thereferenced patent. Transistors Q1 and Q2 are driven in such a manner asto achieve a power factor close to 1.0, and to maintain needed voltageacross C2 and C3. Inductor L1 is also connected through diode D3 andcapacitor C2 to neutral; and inductor L2 is connected through diode D4and capacitor C3 to neutral. When Q1 is turned off after it has beenconducting, current is passed through L1 and D3 to charge capacitor C2,maintaining positive voltage on the +HV rail 35. Likewise, when Q2 isturned off after having been turned on during a negative swing of theline voltage, current from inductor L2 passes through diode D4 andcharges capacitor C3, maintaining negative voltage on high V rail 36.

[0018] Still referring to FIG. 2, HV rails 35 and 36 have connectedtherebetween transistor switches Q3 and Q4 in series, which are drivenat input terminals 38 and 39 by a reference signal in a well knownmanner, so as to alternately switch on during respective half cycles ofpositive and negative going voltage. Diode D5 is placed acrosstransistor Q3, and diode D6 is placed across transistor Q4. The switchedvoltage appearing at the node between transistors Q3 and Q4 is connectedto filtering inductor L3, and the AC output which appears acrosscapacitor C4 drives the load 40 connected between line out and neutral.

[0019] Battery 30 is shown in FIG. 2, having its negative terminalconnected to neutral, but its positive terminal unconnected. Thelongstanding problem in the art, which this invention meets, is how toconnect the battery in such a way as to enable generation of the plusand minus HV rails from such battery at the time of AC input linefailure. What is needed is a simple but reliable circuit which canutilize the inductor and switching components of the PFC circuit, i.e.,inductors L1 and L2, and transistors Q1 and Q2.

[0020] Referring now to FIG. 3, there is shown an improved circuit whichconnects the battery to converter elements of the power factorcorrection circuit of FIG. 2. In addition to the circuit componentsillustrated in FIG. 2, there is illustrated a battery 30 which is tiedat its plus terminal to neutral through diode D9, and at its minusterminal to neutral through diode D10. Bypass capacitors C5 and C6bridge diodes D9 and D10 respectively, and are chosen to have a largecapacitance with respect to the switching frequency of switches Q1 andQ2, which is determined by control circuit 33. The positive terminal ofthe battery is also connected through D7 to a node between D1 and L1,and the negative terminal of the battery is connected through diode D8to a node between D2 and L2. Instead of connecting Q1 and Q2 to neutralas in FIG. 2, the emitter of Q1 is connected to the negative terminal ofthe battery, while the collector of Q2 is connected to the positiveterminal of the battery. Thus, in terms of extra circuit components, theimproved circuit comprises the simple addition of four diodes and twohigh frequency bypass capacitors. During normal operation the battery isbalanced around neutral, and never gets more than a forward biased diodedrop away from neutral, e.g., about one-half to three-fourths volts. Byutilizing a battery that has a voltage less than one-half the peak ofthe incoming AC voltage, the power factor correction circuit operatesover a sufficiently long portion of each cycle to achieve a power factorgreater than 0.9.

[0021] Referring now to FIGS. 4A and 4B, there are illustrated circuitdiagrams showing the equivalent circuit operation under conditions wherethere is a good input on the AC line, and the input voltage is positiveand greater than battery voltage. In FIG. 4A, Q1 is illustrated in an onor closed switch position, and in FIG. 4B is illustrated in an off, oropen switch position. Note that Q1 is turned on only when the voltagepeak is greater than the battery voltage, such that D7 is reversedbiased. In this condition, as illustrated in referenced U.S. Pat. No.4,980,812, capacitor C2 is shunted by Q1 and current builds up ininductor L1. When Q1 opens, as shown in FIG. 4B, L1 acts as a currentgenerator and pumps current into capacitor C2, building up the DCvoltage thereacross. FIGS. 5A and 5B show the equivalent circuit diagramwhen the line terminal is negative and the voltage exceeds the batteryvoltage. In a similar fashion, when Q2 is closed and thus shunts C3,current builds up through L2. When Q2 is opened, current is pumped fromL2 into capacitor C3, thereby generating a negative voltage across C3with respect to neutral. These respective operations generate thepositive and negative HV rails indicated in FIG. 3, in a manner that issubstantially unchanged with respect to the embodiment of U.S. Pat. No.4,980,812. During this typical cycle of operation, forward biased diodeD10 connects current through Q1 while it is closed, and forward biaseddiode D9 is in series with switch Q2 when it is closed, with the resultthat the improved circuit has no appreciable impact on the operation ofthe PFC conversion. During the positive line voltage swing, the negativeterminal of the battery is tied to neutral through D10; during thenegative line voltage swing, the positive terminal of the battery istied to neutral through D9.

[0022] Referring now to FIGS. 6A and 6B, there are illustrated theeffective circuit diagrams for the UPS circuit of this invention duringloss of AC input, i.e., at any time when UPS load is being supplied bythe battery. During this time, the improved switching circuit acts toconnect the battery to alternately charge C2 and C3 so as to maintainthe same plus and minus high voltage rails. During such battery back upoperation, switches Q1 and Q2 are turned on and off independently, byswitch control 33.

[0023] When the AC source voltage drops to an unacceptable level, switchcontrol 33 operates to drive Q1 and Q2 through on-off cycles, at a dutycycle as required to provide a regulated output. Note that each of Q1and Q2 can be switched independently, as may be required for anunbalanced load (not shown unbalanced). Q2 is held off (open) while C2is charged, and Q1 is held off while C3 is charged.

[0024] During the period of time that Q2 is held off, Q1 is firstswitched on and then switched off. FIG. 6A shows Q2 off and Q1 switchedon. Under these circumstances, current flows from the battery throughdiode D7, inductor L1, and back through switch Q1 to the negativeterminal of the battery, building up current flow in inductor L1. At thesame time, remaining current through L2 is discharged through diode D8,diode D10, capacitor C3 and diode D4. When Q1 is turned off (FIG. 6B),the build up of current is passed through diode D3 into capacitor C2,charging it positively with respect to neutral. The current through C2returns through diode D9. At the same time, current from battery 30 goesaround the outer loop of the circuit shown, i.e., through D7, L1, D3,C2, C3, D4, L2 and D8. Following this, the sequence is reversed suchthat Q1 is turned off, and Q2 is alternatingly turned on and off,resulting in the reverse operation which builds up the negative voltageacross capacitor C3. During the battery supply of the output voltage, ifcapacitor C2 and C3 are loaded in a balanced manner, and if C5 and C6have large capacitance for the switching frequency, then the voltageacross each of capacitors C5 and C6 is held substantially constant andhas a value of approximately one-half the voltage of the battery. To theextent that C2 and C3 loading becomes unbalanced, the ratio of thevoltages across C5 and C6 likewise is unbalanced.

[0025] Referring now to FIG. 7A, there is shown a preferred circuit. Inthis embodiment, battery 30 has one terminal (illustrated as thenegative terminal) connected to neutral. The other terminal is connectedthrough switch S1 to D7. Switch S1 is normally open, but is closed bycontrol 33 whenever low line voltage is detected, in a conventionalmanner. Compared to FIG. 3, diode D10 and capacitor C6 are eliminated,and switch S1 is added. FIGS. 7B and 7C illustrate the circuit actionwhen the load is battery-driven. In FIG. 7B, each of switches Q1 and Q2are closed, such that current flows from battery 30 to each inductor L1,L2. In FIG. 7C, Q1 and Q2 are each switched open, so that current flowsfrom L1 to C2, and from L2 to C3. In this embodiment as well, switchcontrol 30 can drive Q1 and Q2 independently when the UPS is in thebattery-driving mode due to low source AC voltage.

[0026] Both the preferred embodiment of FIG. 7A and the embodiment ofFIG. 3 illustrated DC to AC converter (utilizing transistors Q3, Q4),for providing uninterrupted AC output. However, the invention alsoapplies to a supply for providing a DC output, such that no DC to ACinverter is utilized. Thus, in general, the invention comprises anoutput circuit between the HV rails and the output terminals.

[0027] There is thus illustrated a very simple, inexpensive and reliablecircuit which achieves the object of connecting the battery to an UPShaving an uninterrupted neutral from input to output, the batteryconnection being made in such a way as to utilize the PFC circuit forconversion of the battery voltage during times when the battery issupplying output load. At the same time, the circuit ties one terminalof the battery to neutral, or holds the battery balanced around neutral,and does not adversely affect performance of the PFC circuit. Theinvention thus achieves the object of allowing the battery to beconnected to neutral at all times, while utilizing the PFC circuit toconvert the battery output to the HV lines at the time of AC powersource failure.

What is claimed:
 1. An uninterrupted power supply (UPS), having firstand second input terminals for connection to a power line source, one ofsaid terminals being connected to power line neutral, first and secondoutput terminals, one of said output terminals being connected to saidneutral through an uninterrupted conductor, and a battery, comprising apower factor correction (PFC) circuit having an AC to DC convertercircuit, an input connected across said input terminals, and having apositive output terminal providing a positive DC high voltage withrespect to said neutral and a negative output terminal providing anegative high DC voltage with respect to neutral, a high positivevoltage rail connected to said positive output terminal and a negativehigh voltage rail connected to said negative output terminal, an outputcircuit having an input connected across said positive and negativerails, and providing an output to said output terminals, and a batteryconnection circuit connecting said battery to said PFC converter circuitwhereby when the power line voltage fails and said UPS is in batterymode operation, battery voltage is converted through said PFC convertercircuit to supply said positive and negative high voltage rails.
 2. TheUPS of claim 1, wherein said PFC converter circuit comprises a firstinductance and a first capacitor connected between said positive highvoltage rail and neutral, and a second inductor and a second capacitorwhich is connected between said negative high voltage rail and neutral,and wherein said battery connection circuit operatively connects saidbattery to drive each of said first and second inductors during powerline failure.
 3. The UPS as described in claim 1, wherein said PFCconverter circuit comprises first and second switching elements, andfurther comprises switching means for switching said switching elementsunder normal operation and battery mode operation.
 4. The UPS asdescribed in claim 1, wherein said battery has first and second outputterminals and said battery connection circuit connects one of saidterminals directly to said neutral.
 5. The UPS as described in claim 1,wherein said battery has first and second output terminals and whereinsaid battery connection circuit comprises a respective diode connectedbetween neutral and at least one of said battery terminals.
 6. The UPSas described in claim 5, wherein said battery connection circuitbalances said battery around neutral.
 7. The UPS as described in claim4, further comprising a switch connected to the other one of saidbattery terminals, said switch being normally open, and switchingcontrol means for closing said switch when the voltage on said powerline source falls to a predetermined unacceptable level.
 8. The UPS asdescribed in claim 1, wherein said output circuit is a DC to ACconverter.
 9. An uninterrupted power supply (UPS), having first andsecond input terminals for connection to a power line source, the firstof said input terminals being connected to power line neutral, first andsecond output terminals, an uninterrupted neutral connection from saidfirst input terminal to said first output terminal, for connectingneutral directly to said first output terminal, comprising: a rectifiermeans connected to said input terminals for providing positive andnegative rectified voltage outputs, a power factor correction (PFC)circuit connected to the outputs of said rectifier means, said PFCcircuit having an AC to DC converter means for providing positive andnegative DC voltage outputs relative to said neutral connection, abattery having first and second output terminals, one of said terminalsbeing connected directly to said neutral connection, and a connectioncircuit for connecting the other of said battery terminals to said PFCconverter circuit, and an output circuit having an input connectedacross said positive and negative DC outputs and providing an outputacross said output terminals.
 10. The UPS as described in claim 9,wherein said output circuit is a DC to AC converter.
 11. The UPS asdescribed in claim 9, wherein said battery connection circuit comprisesa switch for controllably connecting said battery to said PFC convertercircuit.
 12. The UPS as described in claim 9, comprising control meansfor controlling said PFC converter circuit when the power line source isbelow a predetermined voltage level.
 13. An uninterrupted power supply(UPS) having first and second input terminals for receiving AC powerfrom a power source, one of said input terminals being connected to theneutral of said power source, said UPS providing AC output power to apair of output terminals, said UPS being operable in an AC mode whensaid power source delivers a predetermined satisfactorily high voltageand operable in a battery mode when said power source does not deliversaid satisfactorily high voltage, comprising: only one converter circuitfor providing a DC output; a power factor correction circuit fordelivering a power factor corrected power from said input terminals; abattery for providing energy to said one converter circuit when in saidbattery mode; a DC to AC converter for converting the output of said oneconverter circuit to provide AC power to said output terminals; and anuninterrupted connection for connecting (a) said one input terminalconnected to neutral, (b) one of said battery terminals and (c) one ofsaid AC output terminals, whereby power neutral is connected directly tosaid battery and to a load connected across said AC output terminals.